CA1313295C - Tool for the precise movement of machines - Google Patents
Tool for the precise movement of machinesInfo
- Publication number
- CA1313295C CA1313295C CA000585606A CA585606A CA1313295C CA 1313295 C CA1313295 C CA 1313295C CA 000585606 A CA000585606 A CA 000585606A CA 585606 A CA585606 A CA 585606A CA 1313295 C CA1313295 C CA 1313295C
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- hole
- fulcrum
- actuator member
- clamping arm
- circular
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Abstract
ABSTRACT
A tool for the controlled, precise movement, in the horizontal plane, of machines such as electric motors, gear boxes, compressors and the like, for the purpose of achieving an accurate horizontal alignment between two or more machines.
The tool includes a clamping arm that has a relatively flat rotatable circular actuator member engaged in a hole in the arm. The clamping arm has a lip edge to contact the outer edge of an outwardly extending foot of the machine to be aligned, and in the preferred form of the device, the position of the lip edge with respect to the foot outer edge is adjustable by a thumb screw.
The circular actuator member has an offset fulcrum, and rotation of the actuator member around that offset fulcrum causes lateral movement of the clamping arm. The lip edge of the clamping arm, which is in contact with the outwardly extending foot of the machine being aligned, moves the machine a distance that is a function of the rotational movement of the circular actuator member.
A tool for the controlled, precise movement, in the horizontal plane, of machines such as electric motors, gear boxes, compressors and the like, for the purpose of achieving an accurate horizontal alignment between two or more machines.
The tool includes a clamping arm that has a relatively flat rotatable circular actuator member engaged in a hole in the arm. The clamping arm has a lip edge to contact the outer edge of an outwardly extending foot of the machine to be aligned, and in the preferred form of the device, the position of the lip edge with respect to the foot outer edge is adjustable by a thumb screw.
The circular actuator member has an offset fulcrum, and rotation of the actuator member around that offset fulcrum causes lateral movement of the clamping arm. The lip edge of the clamping arm, which is in contact with the outwardly extending foot of the machine being aligned, moves the machine a distance that is a function of the rotational movement of the circular actuator member.
Description
TOOL FOR THE PRECISE MOVEMENT OF MACHINES
TECHNICAL FIELD
This invention relates to a tool for use in achieving the precise movement of machines such as electric motors, gear boxes and the like, in order to position the machine to achieve an accurate alignment, in the horizontal plane, between two or more machinesO
BACKGROUND ART
To achieve an accurate alignment between two machines such as an electric motor directly coupled to a driven machine requires movement of the electric motor within tolerances that may be as restrictive as + .001"
(or even closer, depending upon the specific equipment involved) in both the vertical and the horizontal planes.
Typically, a driven machine such as just referred to is positioned in a fixed location, and the electric motor that will drive the machine is secured to its sub~base or the supporting floor adjacent to that machine by means of bolts that are inserted with some horizontal clearance through lugs or feet that extend outwardly from the bottom frame or base of the motor.
When the final position of the electric motor is established, these bolts are tightened in threaded engagement with corresponding holes in the sub-base or supporting floor, with the machine in proper alignment (in both the vertical and horizontal directions) with respect to the driven machine.
When the desired position of the motor relative to its driven machine is being established, the alignment in the vertical plane is achieved by raising or lowering the motor by adding or subtracting metal shims located beneath the motor. The raising or lowering of the motor is not critical, as its correct alignment position is established by the shimsO Positioning the motor on the shims achieves accurate alignment in the vertical plane.
In the horizontal plane, however, any movement is critical. Heretofore the most common method used to achieve horizontal alignment was by using a heavy hammer or heavy metal "bumping" bar to tap the motor in the direction required. Since little control can be exPrcised over the force of the blow, or over the sliding friction of the motor, this method results in a too little or too much trial-and-error movement, requiring many moves before an alignment or compromise position is reached, involving much time and patience on the part of the mechanic doing the alignment.
In certain circumstances when the construction of the machine base is suitable, another method of producing horizontal aligning movement may be used. This involves fabricating metal lugs, drilled and tapped to accept a jackbolt, and welding these lugs to the sub-base or supporting floor adjacent to each foot of the motor, with its associated jackbolt directed toward the foot.
The jackbolt is screwed to contact the edge of the foot and push the motor in the direction required.
The jackbolt threads that are in contact with the foot distort as the jac~bolt is turned, and in some cases the jackbolt will bend, making removal difficult if not impossible. Left in position, the lugs and jackbolts are subject to deterioration, making them unusable the next time motor movement is required, and as a result they have to be removed and replaced. Lugs and jackbolts have to be made and fitted to each piece of equipment that is suitable for this method of movement. This method is costly and time consuming.
DISCLOSURE OF INVENTION
Summary Of The Invention The device of this invention is used to accurately position an object such as an electric motor or the like in a predetermined horizontal location.
~3--The device includes a clamping arm having a circular hole adjacent one end, with a lip edge at the opposite end of the arm for contacting an end surface of the object that is to be positioned. A circular actuator member is rotatably engaged in the circular hole of the clamping arm just mentioned.
A cylindrical fulcrum is provided having a central axis, and the circular actuator member has means such as a hole to en~age the fulcrum and permit it to rotate about the fulcrum with an eccentric axis of rotation. The eccentric axis of rotation of the actuator member and the central axis of the fulcrum are colinearO
~ means is provided to hold the fulcrum in a horizontally fixed position. Means is provided for rotating the actuator member in a given angular direction around its eccentric axis of rotation (and around the colinear central axis of the cylindrical fulcrum) to apply a positioning force to the clamping arm in a first horiæontal direction~ The lip edge of the arm then tran~mits that positioning force to the object being accurately positioned. The rotation of the circular actuator member in the given angular direction reduces the distance between the lip edge of the clamping arm and the fulcrum to effect the desired horizontal positional adjustment of the object.
In the preferred embodiment of the device of this invention, the eccentric axis of rotation of the circular actuator member initially intersects the diameter of that member that lies parallel to the lip edge of the clamping arm. In a further feature of the invention, the lip edge of the clamping arm includes ~1) a threaded hole and (2) a member threadedly engaged with that hole and oriented to bear upon the and surface of the object being positioned. This latter feature provi~es an adjustment for whatever variatiGn there may be, depending upon thP
machine being positioned, in the distance from the outer edge of the object against which the lip edge of the 1 31 32~5 clamping arm bears, to that part of the object being positioned in which the cylindrical fulcrum of the device is located.
Two embodiments of the device of the invention are disclosed, depending upon the mode used for final securing of the object being accurately positioned.
Advantages Of The Invention The device of this invention provides a portable, quick~ easy method to move a machine in a controlled, precise manner to achieve an accurate alignment, while being adjustable to suit a range of machine sizes.
A further benefit is a scale or index for measuring the amount of movement made.
Further objects and advantages of my invention will become apparent from a consideration of the drawings and ensuing description thereof.
BRIEF DESCRIPTION OF DRAWINGS
FIG. 1 is a perspective view of one embodiment of the tool of this invention assembled in an operating mode over a machine foot (shown in phantom), which in turn is located above a sub-base or supporting floor (also shown in phantom).
FIG. 2 is a fra~mentary, exploded view showing various component parts of the embodiment of FIG. 1.
FIG. 3 is a fragmentary, sectional view taken through a machine foot and the sub-base on which it rests, showing certain component parts of a second embodiment of this invention.
BEST MODE FOR CARRYING OUT THE INVENTION
Structure Of First Embodiment Of This Invention FIG. 1 gives a perspective view of one embodiment of the tool of this invention in place for use 1 31 3~q5 to produce the pxoper alignment of an electric motor with respect to the machine that the motor drives. FIG. 2 provides a fragmentary, exploded view showing various component parts of the same embodiment of the device.
Clamping arm (1) has a hole (6) at one end, and has a flange or lip edge (3) at its other, outer end.
Flange or lip (3) has a centrally located, threaded hole that receives a bolt or screw (4) threaded into the hole.
Member (4) has a knurled head for grasping by the user of this device (for a purpose to be explained below).
A relatively low circular actuator member (2) has at its upper side a means of engagement (7) with a mechanical device for rotating the circular member.
Actuator member (2) also has an outwardly extending flange (9) at its upper side.
At its lower side, circular actuator member (2) has a hole (8). This hole is offset from the geometric center (12) of actuator member (2) to form an eccentric axis of rotation (13~ for that member (2). Circular actuator member (2) is engageable in hole (6~ in clamping arm (1), and in this position (as is seen in FIG. 1~ is supported by flange (9) rotatably resting on the upper surface of arm (1).
A shaft or journal (5) has an upper, cylindrical, fulcrum portion (16) that is engageable in hole (8) of circular actuator member (2), and a lower portion (17). As indicated in FIG. 1, lower portion (17) of shaft (5) extends, with substantial clearance around it, through a hole in the outwardly extending foot (15) of the electric motor. Representative clearances between lower portion (17) and the hole in outwardly extending foot (15) are provided, for example, by a hole having an inside diameter of 0.56" when lower portion (17) has an outside diameter of 1/2", and by a hole having an inside diameter of 1.19l' for a lower portion (17~ having an outside diameter of 1l'.
The bottom end portion of member (17~ i5 : . ~ , . ;
1 31 32~5 threaded for engagement with a threaded hole in the sub-base or supporting floor (18) (shown in phantom in FIG. 1 on which the electric motor rests. This engagement holds shaft (5), with upper fulcrum portion (16), in a horizontally fixed position.
Intermediate portion (19) of shaft (5), which lies between upper portion (16) and lower porkion (17), forms a shoulder to abut the bottom surface of circular actuator member (2). As will be seen, axis of rotation (~O) of shaft (5) coincides with axis of rotation (13) of actuator (2).
Circular actuator member (2) is shown in FIG. 1 engaging fulcrum portion (16) of shaft or journal (5) in hole (8) in the actuator member, and in turn being engaged in hole (6) in clamping arm (1) while being rotatably supported by flange (9). When actuator member (2) is rotated about axis of rotation (13), the degree of rotation is indicated by the relative position of indicator mark (11) with respect to scale or index (10) on clamping arm (1). Hexagonal part (7) carried by circular actuator member (2) enables that member to be readily rotated using a wrench of any conventional type.
Operation Of The Device Of This Invention As will be seen from FIGS. 1 and 2, when circular actuator member (2) is rotated by turning hexagonal part (7) in the clockwise direction in FIG. 1, the portion of the actuator member that lies diametrically opposite eccentric axis of rotation (13) will apply a horizontally directed force towards the right in that Figure. Since as explained above the fulcrum (16) is horizontally fixed, the force just mentioned will be applied by actuator member (2) to clamping arm ~l). Lip edge (3) then transmits this force to outer edge (143 of outwardly extending foot (15) of the electric motor, and that edge is then moved by the predetermined distance in the desired horizontal direction to bring the electric . .
motor into alignment with the driven machine.
The amount of movement envisioned using this tool is the precise amount of movement that is required to bring an electric motor (for example) or other object into accurate horizontal alignment after initial approximate horizontal alignment of the object has been made. The device of this invention is employed after a determination has been made as to the amount and direction of horizontal movement that will be required to effect an accurate positioning of the object being aligned. As an example, the use of this tool to achieve accurate horizontal positioning of an electric motor will now be described.
The bolt that secures the foot (15) that extends outwardly from the lower frame or base of the electric motor is first removed. The bolt is replaced by the shaft or journal (5), which is threaded into the machine sub-base or supporting floor (18) with the above mentioned substantial clearance in the hole in the outwardly extending foot (15). The top of the shaft or journal (5) extends above the top surface of the foot.
The clamping arm (1) is now placed oYer the electric motor foot (15) in such a way that shaft or journal (5) protrudes through hole (6) in the arm (1), and lip (3) covers the outer edge of the foot. Circular actuator member (2) is then placed into hole ~6) in body (1). In this position it seats fulcrum portion (16) of shaft or journal (5) in hole (8), with flange (9) supporting actuator member (2) by rotatable engagement with the top surface of arm (1).
The screw (4) in lip (3) is then tightened to contact edye (14) of machine foot (15). This will provide an adjustment for variations, from one electric motor to another, in the distance from outer edge (14) of foot (15) to the center of the hole in the foot.
- 35 In this initial position of cir~ular member (2), its diameter D ~see FIG. 1) that is intersected by eccentric axis of rotation (13) is preferably parallel to 1 31 32~5 edge (14) of el~ctric motor foot (15).
The circular actuator member (2), a~ter being engaged by a mechanical device such as a wrench at (7), is now rotated, moving the circular actuator member about its eccentric axis of rotation (13) through 90 or a porkion thereof, away from contacted edge (14~ of electric motor foot (15). This rotational movement is converted into lateral, horizontally directed, positioning movement of clamping arm (1), through the engagement of circular actuator member (2~ in hole (6) of arm (1) and the rotation of member (2) around its eccentric axis of rotation (13). The amount of lateral positioning movement of clamping arm (1) is a function of the rotation of actuator member (2), which rotation can be measured by reading the scale or index ~10) against the mark (11) on member (2~.
As one skilled in the art will understand, if circular actuator member (2) is rotated more than 90, no further lateral, horizontally directed, positioning force will be applied by that member to clamping arm (1). It will be similarly apparent that the maximum effect of the rotation of actuator member (2) through the indicated quadrant will be achieved when (as i5 the case with embodiment of FIG. 1) the eccentric axis of rotation (13) of actuator ~2) lies initially upon the diameter D of member (2) that is parallel to outer edge (14) of the object (15) to be moved.
It will be further understood that if eccentric axis of rotation (13) is located in the opposite half of circular actuator member (2) from that shown in FIG. 2, the rotation of member (2) to apply a horizontal positioning force from that member to clamping arm (1) must be in the counterclockwise direction as seen in FIG.
1~
When the desired accurate horizontal position for the electric motor being aligned has been achieved the tool is removed. Shaft or journal (5) is then _9_ replaced with the typical threaded s~curing bolt that (as discussed above) was removed from its threaded engagement with the correspondingly threaded hole in the sub-base or supporting floor (18) for the electric motor in order to utilize the tool of this invention to achieve the necessary accurate alignment after limited, approximate alignment has been established.
Structure Of Second Embodiment Of This Invention The device of this invention has been described for use with a machine to be aligned that has a securing bolt with a head that protrudes above the outwardly extending foot of the machine and a threaded shaft portion that threadedly engages a hole in the sub-base or supporting floor on which the machine rests. The device of this invention is also useful to achi~ve accurate horizontal alignment of a second category of machines in which the securing memher for each outwardly extending machine foot comprises a threaded bolt or post that extends upward from the sub-base or supporting floor and through a hole in the machine foot, to receive a threaded nut to be tightened down on the bolt or post.
FIG~ 3 is a fragmentary, sectional view showing certain component parts of a second embodiment of this invention that is useful with the second category of machines just mentioned. Here, again, outwardly extending foot (15) of the machine being positioned rests on sub-base or supporting floor (18), but the means ~or holding the fulcrum in a horizontally fixed position is somewhat different than in the case of the first embodiment that is illustrated in FIGo 2 and discussed above.
As seen in FIG~ 31 shaft (5') has an upper, cylindrical portion (16') that extends above machine foot (15) to provide a fulcrum. Lower portion (17') of shaft (5') is threaded as in the first embodiment. However, instead of being threadably engaged with a threaded hole in sub-base or supporting floor ~18), it is threadably -- 1 31 3~95 engaged with a collar ~21), which is internally threaded (22) and has an outside diameter selected to fit into a hole (23) in the sub-base. Collar (21) has an outwardly extending flange (24) on its bottom side to allow the collar to be seated in the hole in the sub-base, with the outwardly extending flanga pressing against the bottom surface (25) of the sub-base (18).
Shoulder (19') carries an outwardly extending flange that is seated against the top surface of machine foot (15). Shaft (5') has a central axis (20)', as shown.
Operation Of Second Embodiment Of This Invention In the use of this second embodiment o~ the device of this invention, shaft (5') is inserted through the holes in machine foot (15) and sub-base (18), with the outwardly extending flange (19') resting on the machine foot. Threaded collar (21) is screwed onto bottom portion (17') of shaft (5'), and enters into the hole in sub-base (18) to seat the outwardly extending flange (24) of collar (21) against the bottom surface (25) of the sub-base.
The collar (21) is then tishtened to a snug fit against the su~-base (18). This produces a fixed horizontal position for shaft (5'), and at the same time allows movement between the outwardly extending flange of member (l9') and machine Eoot (15). Circular actuator member (2) is then inserted in hole ~6) in clamping arm (1), and hole (8) in member (2) is engaged with the fulcrum (16'). Lip edge (3) of arm ~1) is positioned at this time adjacent to outer edge (14) of machine foot (15), and threaded bolt (4) is screwed up against edge (14), as d~scribed above with the first embodiment of this invention.
Hexagonal part (7) is then rotated in the clockwise direction in FIG. 1, as was done with the first embodiment of this invention. Rotation of circular actuator member (2) applies a horizontal positioning force against the wall of hole (6) and clamping arm (1), which force in turn is transmitted to lip edge (3) and the threaded end of bolt ~4) of body (1). Because the fulcrum (16') is maintained in a fixed horizontal position by collar (21), the force applied by ~hreaded bolt ~4) against machine foot (15) moves that machine foot the predetermined distance to the right in FIG. 1.
The device of this invention has been described with respect to the horizontal alignment of an electric motor. The device is also useful, of course, in achieving the necessary horizontal alignment of gear boxes, generators, compressors, turbines, or similar machines or equipment.
The above description is a description of two preferred embodiments of the device of this invention, and should not be construed as creating any limitations on the scope of the invention.
TECHNICAL FIELD
This invention relates to a tool for use in achieving the precise movement of machines such as electric motors, gear boxes and the like, in order to position the machine to achieve an accurate alignment, in the horizontal plane, between two or more machinesO
BACKGROUND ART
To achieve an accurate alignment between two machines such as an electric motor directly coupled to a driven machine requires movement of the electric motor within tolerances that may be as restrictive as + .001"
(or even closer, depending upon the specific equipment involved) in both the vertical and the horizontal planes.
Typically, a driven machine such as just referred to is positioned in a fixed location, and the electric motor that will drive the machine is secured to its sub~base or the supporting floor adjacent to that machine by means of bolts that are inserted with some horizontal clearance through lugs or feet that extend outwardly from the bottom frame or base of the motor.
When the final position of the electric motor is established, these bolts are tightened in threaded engagement with corresponding holes in the sub-base or supporting floor, with the machine in proper alignment (in both the vertical and horizontal directions) with respect to the driven machine.
When the desired position of the motor relative to its driven machine is being established, the alignment in the vertical plane is achieved by raising or lowering the motor by adding or subtracting metal shims located beneath the motor. The raising or lowering of the motor is not critical, as its correct alignment position is established by the shimsO Positioning the motor on the shims achieves accurate alignment in the vertical plane.
In the horizontal plane, however, any movement is critical. Heretofore the most common method used to achieve horizontal alignment was by using a heavy hammer or heavy metal "bumping" bar to tap the motor in the direction required. Since little control can be exPrcised over the force of the blow, or over the sliding friction of the motor, this method results in a too little or too much trial-and-error movement, requiring many moves before an alignment or compromise position is reached, involving much time and patience on the part of the mechanic doing the alignment.
In certain circumstances when the construction of the machine base is suitable, another method of producing horizontal aligning movement may be used. This involves fabricating metal lugs, drilled and tapped to accept a jackbolt, and welding these lugs to the sub-base or supporting floor adjacent to each foot of the motor, with its associated jackbolt directed toward the foot.
The jackbolt is screwed to contact the edge of the foot and push the motor in the direction required.
The jackbolt threads that are in contact with the foot distort as the jac~bolt is turned, and in some cases the jackbolt will bend, making removal difficult if not impossible. Left in position, the lugs and jackbolts are subject to deterioration, making them unusable the next time motor movement is required, and as a result they have to be removed and replaced. Lugs and jackbolts have to be made and fitted to each piece of equipment that is suitable for this method of movement. This method is costly and time consuming.
DISCLOSURE OF INVENTION
Summary Of The Invention The device of this invention is used to accurately position an object such as an electric motor or the like in a predetermined horizontal location.
~3--The device includes a clamping arm having a circular hole adjacent one end, with a lip edge at the opposite end of the arm for contacting an end surface of the object that is to be positioned. A circular actuator member is rotatably engaged in the circular hole of the clamping arm just mentioned.
A cylindrical fulcrum is provided having a central axis, and the circular actuator member has means such as a hole to en~age the fulcrum and permit it to rotate about the fulcrum with an eccentric axis of rotation. The eccentric axis of rotation of the actuator member and the central axis of the fulcrum are colinearO
~ means is provided to hold the fulcrum in a horizontally fixed position. Means is provided for rotating the actuator member in a given angular direction around its eccentric axis of rotation (and around the colinear central axis of the cylindrical fulcrum) to apply a positioning force to the clamping arm in a first horiæontal direction~ The lip edge of the arm then tran~mits that positioning force to the object being accurately positioned. The rotation of the circular actuator member in the given angular direction reduces the distance between the lip edge of the clamping arm and the fulcrum to effect the desired horizontal positional adjustment of the object.
In the preferred embodiment of the device of this invention, the eccentric axis of rotation of the circular actuator member initially intersects the diameter of that member that lies parallel to the lip edge of the clamping arm. In a further feature of the invention, the lip edge of the clamping arm includes ~1) a threaded hole and (2) a member threadedly engaged with that hole and oriented to bear upon the and surface of the object being positioned. This latter feature provi~es an adjustment for whatever variatiGn there may be, depending upon thP
machine being positioned, in the distance from the outer edge of the object against which the lip edge of the 1 31 32~5 clamping arm bears, to that part of the object being positioned in which the cylindrical fulcrum of the device is located.
Two embodiments of the device of the invention are disclosed, depending upon the mode used for final securing of the object being accurately positioned.
Advantages Of The Invention The device of this invention provides a portable, quick~ easy method to move a machine in a controlled, precise manner to achieve an accurate alignment, while being adjustable to suit a range of machine sizes.
A further benefit is a scale or index for measuring the amount of movement made.
Further objects and advantages of my invention will become apparent from a consideration of the drawings and ensuing description thereof.
BRIEF DESCRIPTION OF DRAWINGS
FIG. 1 is a perspective view of one embodiment of the tool of this invention assembled in an operating mode over a machine foot (shown in phantom), which in turn is located above a sub-base or supporting floor (also shown in phantom).
FIG. 2 is a fra~mentary, exploded view showing various component parts of the embodiment of FIG. 1.
FIG. 3 is a fragmentary, sectional view taken through a machine foot and the sub-base on which it rests, showing certain component parts of a second embodiment of this invention.
BEST MODE FOR CARRYING OUT THE INVENTION
Structure Of First Embodiment Of This Invention FIG. 1 gives a perspective view of one embodiment of the tool of this invention in place for use 1 31 3~q5 to produce the pxoper alignment of an electric motor with respect to the machine that the motor drives. FIG. 2 provides a fragmentary, exploded view showing various component parts of the same embodiment of the device.
Clamping arm (1) has a hole (6) at one end, and has a flange or lip edge (3) at its other, outer end.
Flange or lip (3) has a centrally located, threaded hole that receives a bolt or screw (4) threaded into the hole.
Member (4) has a knurled head for grasping by the user of this device (for a purpose to be explained below).
A relatively low circular actuator member (2) has at its upper side a means of engagement (7) with a mechanical device for rotating the circular member.
Actuator member (2) also has an outwardly extending flange (9) at its upper side.
At its lower side, circular actuator member (2) has a hole (8). This hole is offset from the geometric center (12) of actuator member (2) to form an eccentric axis of rotation (13~ for that member (2). Circular actuator member (2) is engageable in hole (6~ in clamping arm (1), and in this position (as is seen in FIG. 1~ is supported by flange (9) rotatably resting on the upper surface of arm (1).
A shaft or journal (5) has an upper, cylindrical, fulcrum portion (16) that is engageable in hole (8) of circular actuator member (2), and a lower portion (17). As indicated in FIG. 1, lower portion (17) of shaft (5) extends, with substantial clearance around it, through a hole in the outwardly extending foot (15) of the electric motor. Representative clearances between lower portion (17) and the hole in outwardly extending foot (15) are provided, for example, by a hole having an inside diameter of 0.56" when lower portion (17) has an outside diameter of 1/2", and by a hole having an inside diameter of 1.19l' for a lower portion (17~ having an outside diameter of 1l'.
The bottom end portion of member (17~ i5 : . ~ , . ;
1 31 32~5 threaded for engagement with a threaded hole in the sub-base or supporting floor (18) (shown in phantom in FIG. 1 on which the electric motor rests. This engagement holds shaft (5), with upper fulcrum portion (16), in a horizontally fixed position.
Intermediate portion (19) of shaft (5), which lies between upper portion (16) and lower porkion (17), forms a shoulder to abut the bottom surface of circular actuator member (2). As will be seen, axis of rotation (~O) of shaft (5) coincides with axis of rotation (13) of actuator (2).
Circular actuator member (2) is shown in FIG. 1 engaging fulcrum portion (16) of shaft or journal (5) in hole (8) in the actuator member, and in turn being engaged in hole (6) in clamping arm (1) while being rotatably supported by flange (9). When actuator member (2) is rotated about axis of rotation (13), the degree of rotation is indicated by the relative position of indicator mark (11) with respect to scale or index (10) on clamping arm (1). Hexagonal part (7) carried by circular actuator member (2) enables that member to be readily rotated using a wrench of any conventional type.
Operation Of The Device Of This Invention As will be seen from FIGS. 1 and 2, when circular actuator member (2) is rotated by turning hexagonal part (7) in the clockwise direction in FIG. 1, the portion of the actuator member that lies diametrically opposite eccentric axis of rotation (13) will apply a horizontally directed force towards the right in that Figure. Since as explained above the fulcrum (16) is horizontally fixed, the force just mentioned will be applied by actuator member (2) to clamping arm ~l). Lip edge (3) then transmits this force to outer edge (143 of outwardly extending foot (15) of the electric motor, and that edge is then moved by the predetermined distance in the desired horizontal direction to bring the electric . .
motor into alignment with the driven machine.
The amount of movement envisioned using this tool is the precise amount of movement that is required to bring an electric motor (for example) or other object into accurate horizontal alignment after initial approximate horizontal alignment of the object has been made. The device of this invention is employed after a determination has been made as to the amount and direction of horizontal movement that will be required to effect an accurate positioning of the object being aligned. As an example, the use of this tool to achieve accurate horizontal positioning of an electric motor will now be described.
The bolt that secures the foot (15) that extends outwardly from the lower frame or base of the electric motor is first removed. The bolt is replaced by the shaft or journal (5), which is threaded into the machine sub-base or supporting floor (18) with the above mentioned substantial clearance in the hole in the outwardly extending foot (15). The top of the shaft or journal (5) extends above the top surface of the foot.
The clamping arm (1) is now placed oYer the electric motor foot (15) in such a way that shaft or journal (5) protrudes through hole (6) in the arm (1), and lip (3) covers the outer edge of the foot. Circular actuator member (2) is then placed into hole ~6) in body (1). In this position it seats fulcrum portion (16) of shaft or journal (5) in hole (8), with flange (9) supporting actuator member (2) by rotatable engagement with the top surface of arm (1).
The screw (4) in lip (3) is then tightened to contact edye (14) of machine foot (15). This will provide an adjustment for variations, from one electric motor to another, in the distance from outer edge (14) of foot (15) to the center of the hole in the foot.
- 35 In this initial position of cir~ular member (2), its diameter D ~see FIG. 1) that is intersected by eccentric axis of rotation (13) is preferably parallel to 1 31 32~5 edge (14) of el~ctric motor foot (15).
The circular actuator member (2), a~ter being engaged by a mechanical device such as a wrench at (7), is now rotated, moving the circular actuator member about its eccentric axis of rotation (13) through 90 or a porkion thereof, away from contacted edge (14~ of electric motor foot (15). This rotational movement is converted into lateral, horizontally directed, positioning movement of clamping arm (1), through the engagement of circular actuator member (2~ in hole (6) of arm (1) and the rotation of member (2) around its eccentric axis of rotation (13). The amount of lateral positioning movement of clamping arm (1) is a function of the rotation of actuator member (2), which rotation can be measured by reading the scale or index ~10) against the mark (11) on member (2~.
As one skilled in the art will understand, if circular actuator member (2) is rotated more than 90, no further lateral, horizontally directed, positioning force will be applied by that member to clamping arm (1). It will be similarly apparent that the maximum effect of the rotation of actuator member (2) through the indicated quadrant will be achieved when (as i5 the case with embodiment of FIG. 1) the eccentric axis of rotation (13) of actuator ~2) lies initially upon the diameter D of member (2) that is parallel to outer edge (14) of the object (15) to be moved.
It will be further understood that if eccentric axis of rotation (13) is located in the opposite half of circular actuator member (2) from that shown in FIG. 2, the rotation of member (2) to apply a horizontal positioning force from that member to clamping arm (1) must be in the counterclockwise direction as seen in FIG.
1~
When the desired accurate horizontal position for the electric motor being aligned has been achieved the tool is removed. Shaft or journal (5) is then _9_ replaced with the typical threaded s~curing bolt that (as discussed above) was removed from its threaded engagement with the correspondingly threaded hole in the sub-base or supporting floor (18) for the electric motor in order to utilize the tool of this invention to achieve the necessary accurate alignment after limited, approximate alignment has been established.
Structure Of Second Embodiment Of This Invention The device of this invention has been described for use with a machine to be aligned that has a securing bolt with a head that protrudes above the outwardly extending foot of the machine and a threaded shaft portion that threadedly engages a hole in the sub-base or supporting floor on which the machine rests. The device of this invention is also useful to achi~ve accurate horizontal alignment of a second category of machines in which the securing memher for each outwardly extending machine foot comprises a threaded bolt or post that extends upward from the sub-base or supporting floor and through a hole in the machine foot, to receive a threaded nut to be tightened down on the bolt or post.
FIG~ 3 is a fragmentary, sectional view showing certain component parts of a second embodiment of this invention that is useful with the second category of machines just mentioned. Here, again, outwardly extending foot (15) of the machine being positioned rests on sub-base or supporting floor (18), but the means ~or holding the fulcrum in a horizontally fixed position is somewhat different than in the case of the first embodiment that is illustrated in FIGo 2 and discussed above.
As seen in FIG~ 31 shaft (5') has an upper, cylindrical portion (16') that extends above machine foot (15) to provide a fulcrum. Lower portion (17') of shaft (5') is threaded as in the first embodiment. However, instead of being threadably engaged with a threaded hole in sub-base or supporting floor ~18), it is threadably -- 1 31 3~95 engaged with a collar ~21), which is internally threaded (22) and has an outside diameter selected to fit into a hole (23) in the sub-base. Collar (21) has an outwardly extending flange (24) on its bottom side to allow the collar to be seated in the hole in the sub-base, with the outwardly extending flanga pressing against the bottom surface (25) of the sub-base (18).
Shoulder (19') carries an outwardly extending flange that is seated against the top surface of machine foot (15). Shaft (5') has a central axis (20)', as shown.
Operation Of Second Embodiment Of This Invention In the use of this second embodiment o~ the device of this invention, shaft (5') is inserted through the holes in machine foot (15) and sub-base (18), with the outwardly extending flange (19') resting on the machine foot. Threaded collar (21) is screwed onto bottom portion (17') of shaft (5'), and enters into the hole in sub-base (18) to seat the outwardly extending flange (24) of collar (21) against the bottom surface (25) of the sub-base.
The collar (21) is then tishtened to a snug fit against the su~-base (18). This produces a fixed horizontal position for shaft (5'), and at the same time allows movement between the outwardly extending flange of member (l9') and machine Eoot (15). Circular actuator member (2) is then inserted in hole ~6) in clamping arm (1), and hole (8) in member (2) is engaged with the fulcrum (16'). Lip edge (3) of arm ~1) is positioned at this time adjacent to outer edge (14) of machine foot (15), and threaded bolt (4) is screwed up against edge (14), as d~scribed above with the first embodiment of this invention.
Hexagonal part (7) is then rotated in the clockwise direction in FIG. 1, as was done with the first embodiment of this invention. Rotation of circular actuator member (2) applies a horizontal positioning force against the wall of hole (6) and clamping arm (1), which force in turn is transmitted to lip edge (3) and the threaded end of bolt ~4) of body (1). Because the fulcrum (16') is maintained in a fixed horizontal position by collar (21), the force applied by ~hreaded bolt ~4) against machine foot (15) moves that machine foot the predetermined distance to the right in FIG. 1.
The device of this invention has been described with respect to the horizontal alignment of an electric motor. The device is also useful, of course, in achieving the necessary horizontal alignment of gear boxes, generators, compressors, turbines, or similar machines or equipment.
The above description is a description of two preferred embodiments of the device of this invention, and should not be construed as creating any limitations on the scope of the invention.
Claims (6)
1. A device for accurately positioning an object in a predetermined horizontal location, which comprises:
(a) a clamping arm having a circular hole adjacent one end, the opposite end of said arm having a lip edge for contacting an end surface of said object to be positioned;
(b) a circular actuator member rotatably engaged in the aforesaid circular hole in said clamping arm;
(c) means providing a cylindrical fulcrum having a central axis, said fulcrum-providing means being seated within a hole in said object to be positioned and having substantial clearance with said hole, said circular actuator member having means to engage said fulcrum to rotate about the fulcrum with an eccentric axis of rotation, said eccentric axis of rotation of the circular actuator member and said central axis of the fulcrum being colinear;
(d) means holding said fulcrum in a horizontally fixed position; and (e) means for rotating said circular actuator member in a given angular direction around its aforesaid eccentric axis of rotation, and around said colinear central axis of said cylindrical fulcrum, to apply a positioning force to said clamping arm in a first horizontal direction, the lip edge of said arm transmitting said positioning force to said object in said first horizontal direction, rotation of said circular actuator member in said given angular direction reducing the distance between said lip edge and said fulcrum to thereby effect horizontal positional adjustment of said object.
(a) a clamping arm having a circular hole adjacent one end, the opposite end of said arm having a lip edge for contacting an end surface of said object to be positioned;
(b) a circular actuator member rotatably engaged in the aforesaid circular hole in said clamping arm;
(c) means providing a cylindrical fulcrum having a central axis, said fulcrum-providing means being seated within a hole in said object to be positioned and having substantial clearance with said hole, said circular actuator member having means to engage said fulcrum to rotate about the fulcrum with an eccentric axis of rotation, said eccentric axis of rotation of the circular actuator member and said central axis of the fulcrum being colinear;
(d) means holding said fulcrum in a horizontally fixed position; and (e) means for rotating said circular actuator member in a given angular direction around its aforesaid eccentric axis of rotation, and around said colinear central axis of said cylindrical fulcrum, to apply a positioning force to said clamping arm in a first horizontal direction, the lip edge of said arm transmitting said positioning force to said object in said first horizontal direction, rotation of said circular actuator member in said given angular direction reducing the distance between said lip edge and said fulcrum to thereby effect horizontal positional adjustment of said object.
2. The horizontal positioning device of claim 1 in which said eccentric axis of rotation of said circular actuator member intersects the diameter of the actuator member that lies initially parallel to the aforesaid lip edge of said clamping arm.
3. The horizontal positioning device of claim 1 in which the aforesaid lip edge of said clamping arm includes:
(a) a threaded hole, and (b) a member threadedly engaged with said hole and oriented to bear upon said end surface of the object being positioned.
(a) a threaded hole, and (b) a member threadedly engaged with said hole and oriented to bear upon said end surface of the object being positioned.
4. The horizontal positioning device of claim 1 in which:
(a) said means providing a cylindrical fulcrum is a shaft having (i) an upper cylindrical portion, (ii) an intermediate portion, and (iii) a lower threaded portion, (b) said means to engage said upper, cylindrical, fulcrum portion of said shaft is a circular hole in the bottom portion of said circular actuator member, in which hole said fulcrum portion is rotatably seated, (c) said intermediate portion of the shaft is seated within the aforesaid hole in said object to be positioned and has substantial clearance with said hole, and (d) said lower threaded portion of the shaft is adapted to be screwed into a threaded hole having a fixed horizontal position.
(a) said means providing a cylindrical fulcrum is a shaft having (i) an upper cylindrical portion, (ii) an intermediate portion, and (iii) a lower threaded portion, (b) said means to engage said upper, cylindrical, fulcrum portion of said shaft is a circular hole in the bottom portion of said circular actuator member, in which hole said fulcrum portion is rotatably seated, (c) said intermediate portion of the shaft is seated within the aforesaid hole in said object to be positioned and has substantial clearance with said hole, and (d) said lower threaded portion of the shaft is adapted to be screwed into a threaded hole having a fixed horizontal position.
5. The horizontal positioning device of claim 1 in which:
(a) said means providing a cylindrical fulcrum is a shaft having (i) an upper, cylindrical, fulcrum portion, (ii) an intermediate portion, (iii) a lower threaded portion, and (iv) a flange extending outwardly from said shaft between said upper portion and said intermediate portion to overlie said object to be positioned, (b) said means to engage said upper, cylindrical, fulcrum portion of said shaft is a circular hole in the bottom portion of said circular actuator member, in which hole said fulcrum portion is rotatably seated, (c) said intermediate portion of said shaft is seated within the aforesaid hole in said object to be positioned and has substantial clearance with said hole, and (d) a threaded collar is provided for threaded engagement with the aforesaid lower threaded portion of said shaft, said collar being restrained against horizontal movement.
(a) said means providing a cylindrical fulcrum is a shaft having (i) an upper, cylindrical, fulcrum portion, (ii) an intermediate portion, (iii) a lower threaded portion, and (iv) a flange extending outwardly from said shaft between said upper portion and said intermediate portion to overlie said object to be positioned, (b) said means to engage said upper, cylindrical, fulcrum portion of said shaft is a circular hole in the bottom portion of said circular actuator member, in which hole said fulcrum portion is rotatably seated, (c) said intermediate portion of said shaft is seated within the aforesaid hole in said object to be positioned and has substantial clearance with said hole, and (d) a threaded collar is provided for threaded engagement with the aforesaid lower threaded portion of said shaft, said collar being restrained against horizontal movement.
6. The horizontal positioning device of claim 4 or 5 in which:
(a) the aforesaid lip edge of said clamping arm has a threaded hole, and a member that is threadedly engaged with said hole and is oriented to bear upon said end surface of the object being positioned, and (b) said eccentric axis of rotation of said circular actuator member intersects the diameter of the actuator member that lies initially parallel to the aforesaid lip edge of said clamping arm.
(a) the aforesaid lip edge of said clamping arm has a threaded hole, and a member that is threadedly engaged with said hole and is oriented to bear upon said end surface of the object being positioned, and (b) said eccentric axis of rotation of said circular actuator member intersects the diameter of the actuator member that lies initially parallel to the aforesaid lip edge of said clamping arm.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CA000585606A CA1313295C (en) | 1988-12-12 | 1988-12-12 | Tool for the precise movement of machines |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CA000585606A CA1313295C (en) | 1988-12-12 | 1988-12-12 | Tool for the precise movement of machines |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CA1313295C true CA1313295C (en) | 1993-02-02 |
Family
ID=4139270
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CA000585606A Expired - Fee Related CA1313295C (en) | 1988-12-12 | 1988-12-12 | Tool for the precise movement of machines |
Country Status (1)
| Country | Link |
|---|---|
| CA (1) | CA1313295C (en) |
-
1988
- 1988-12-12 CA CA000585606A patent/CA1313295C/en not_active Expired - Fee Related
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| MKLA | Lapsed |